Engineering Solutions for a Sustainable Future - Exploring Mechanical Engineering's Crucial Function in Contesting Climate Alteration and Environmental Degradation Intended for Nurturing Sustainable Development Goals (SDGS)
DOI:
https://doi.org/10.58213/vidhyayana.v10isi3.2200Keywords:
Environmental Concerns, Mechanical Designing, Maintainability Challenges, Businesses Hook, Environmental Impression, Imaginative Instruments and Methods, Maintainable Arrangements, The Crossing point of Innovation and Maintainability, Energy-Efficient Plans, Improvement of Renewable Vitality Frameworks, Expecting Future Challenges, Proactive Plan and Advancement, Intrigue Collaboration, Potential for Designing Headways, Cultivate an Economical Future, Catalyst for Alter, Driving Society, More Maintainable and Versatile TomorrowAbstract
In a time where natural concerns have come to a basic crossroads, the part of mechanical designing in tending to supportability challenges has never been more essential. As businesses hook with the critical requirement diminishing their biological impression, mechanical engineers stand at the bleeding edge, prepared with imaginative devices and strategies to make maintainable arrangements. This presentation serves as a guide for understanding how mechanical designing can successfully contribute to understanding the squeezing issues of asset consumption, vitality utilization, and squander administration. By looking at different procedures utilized inside this teaching, we will investigate the crossing point of innovation and supportability, highlighting particular case ponders that exhibit effective applications. From energy-efficient plans to the improvement of renewable vitality frameworks, mechanical engineers are not as it were reacting to existing issues but are moreover expecting future challenges through proactive plans and advancement. Moreover, this talk will include the significance of intriguing collaboration, emphasizing how organizations between mechanical engineers and other areas can lead to all-encompassing arrangements. As we dig more profound into this investigation, we point to rouse a sense of good faith with respect to the potential for designing headways to cultivate a maintainable future. Eventually, this system will emphasize the imperative part of mechanical designing as a catalyst for alter, driving society toward a more maintainable and versatile tomorrow.
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References
Böhringer, C., Carbone, J. C., & Rutherford, T. F. (2017). The role of renewable energy in achieving the climate goals: A model-based analysis. Energy Economics, 64, 127-137.
Demirbas, A. (2004). Waste management, waste-to-energy conversion technologies, and their impact on the environment. Energy Sources, 26(10), 947-959.
Ghaffour, N., Lattemann, S., & Missimer, T. M. (2013). Technical and economic feasibility of a renewable energy-powered desalination plant. Desalination, 309, 29-36.
Kaldellis, J. K., & Zafirakis, D. (2007). The wind energy evolution: A short guide for the engineers. Renewable Energy, 32(8), 1346-1356.
Mann, K. L., & Duffy, K. J. (2020). Waste management practices and their impact on climate change. Environmental Science & Technology, 54(1), 10-25.
Rockström, J., Steffen, W., Noone, K., et al. (2009). A safe operating space for humanity. Nature, 461(7263), 472-475.
Sullivan, J. L., et al. (2020). An overview of the global transportation sector: Trends and emissions. Transport Reviews, 40(1), 1-24.
Thompson, R., et al. (2017). Light-weighting in automotive applications: Current practices and opportunities. Journal of Engineering Materials and Technology, 139(1), 1-14.
Zhang, Y., et al. (2021). The application of artificial intelligence in waste management: A review. Waste Management, 119, 367-378.
Zhou, Y., et al. (2018). Membrane technology for water purification: State-of-the-art and future prospects. Environmental Science & Technology, 52(17), 10115-10126.
